蛋白聚集小体检测试剂盒
PROTEOSTAT® Aggresome detection kit
◆原理
聚集小体(Aggresome)是由一群不正常堆叠在一起的蛋白质所形成的包涵体(Inclusion Bodies)。聚集小体的出现往往也表明细胞正处于某种应激状态,比如高温、病毒感染、活性氧自由基攻击等。聚集体通常是响应细胞应激而形成,并通过分离错误折叠的蛋白质提供细胞保护机制,最终导致它们被自噬清除。此外,蛋白质聚集体的形成是多种人类疾病的标志,例如阿尔茨海默氏症、帕金森氏症、肌萎缩侧索硬化症或酒精性肝病。
PROTEOSTAT® Aggresome detection kit中包含的 PROTEOSTAT® 是一种分子转子染料,在溶液中沿着单个中心键的自由分子内旋转可防止荧光产生。当它特异地插入到错误折叠和聚集的蛋白中的交叉β-sheet四级结构中,旋转受到抑制并导致发出强烈的荧光。
PROTEOSTAT® 聚集小体检测试剂盒提供了一种快速、特异、定量的方法来标记细胞中的聚集小体,且无需进行人工蛋白定点突变。PROTEOSTAT® 染料已在广泛的条件下对多种小分子调节剂进行验证,适用于具有治疗价值的化学物的筛选。此外,本试剂盒还适用于多重免疫荧光,以在自噬和聚集体形成的背景下研究您的目标分子。
◆试剂盒组成
组分 | 包装 |
PROTEOSTAT® Aggresome Detection Reagent | 10 μL |
Hoechst 33342 Nuclear Stain | 50 μL |
Proteasome Inhibitor (MG-132) | 120 nM |
10×Assay Buffer | 25 mL |
◆特点
● 提供基于细胞的灵敏的药物反应性测定,以在真实的细胞环境中识别与神经退行性疾病相关的抑制剂
● 可靠且简单的检测,不需要非生理性蛋白质突变或基因工程细胞系
● 作用条件广泛,适用于筛选具有潜在治疗价值的小分子化合物
● 已进行优化以兼容免疫染色
● 可通过流式细胞术轻松量化聚集体和相关包涵体
● 可用于神经退行性疾病、肝病、毒理学研究等的研究
◆案例・应用
■ 应用实例 1:流式细胞术检测聚集小体
流式细胞术的分析:Jurkat细胞在37°C下用 0.2% DMSO对照或用5 µM MG-132诱导过夜。处理后,将细胞固定并与PROTEOSTAT® 染料一起孵育,无需洗涤即通过流式细胞术在FL3通道中使用488 nm激光进行分析。在 MG-132处理的细胞中,红色荧光信号增加约3倍。所描述的测定允许评估蛋白质聚集的影响。
■ 应用实例 2:PROTEOSTAT® 染料与荧光染料的应用
荧光显微镜:含有蛋白聚集体的HeLa细胞,用 5 µM MG-132蛋白酶体抑制剂(右)处理12小时,通过 PROTEOSTAT®(红色)检测并用Hoechst 33342复染。左侧的为未经处理的对照。
荧光显微镜:含有蛋白聚集体的HeLa细胞,用 5μM MG-132蛋白酶体抑制剂处理12小时,通过PROTEOSTAT® 聚集体染料(左上)检测,显示与荧光素-p62抗体(右上)和复合图像(中下)的共定位
■ 应用实例 3:不同搅拌速率对蛋白聚集的影响
使用本产品检测后,可知搅拌速度越快,蛋白聚集程度越大。
■ 应用实例 4:蛋氨酸氧化可抑制蛋白聚集
蓝色曲线为对照,没有搅拌;在搅拌速度在300 rpm下, 绿色曲线与红色曲线分别表示蛋氨酸被氧化后的蛋白聚集情况。
使用本产品检测后,可知蛋氨酸被氧化后可抑制蛋白聚集。
■ 应用实例 5 :内质网应激相关细胞自噬产生蛋白聚集小体
分别25,50,75 mmCQ,100 nM的thapsigargin(TG)或5mM的MG-132处理K562细胞24小时。然后在温室下用PROTEOSTAT® (1:10,000)固定并透化细胞30min。接着在BD流式细胞仪LSR II的蓝色610/20 nm的通道分析细胞(30,000)。
图片来源:Courtesy of the Flow Cytometry Core Facility, Blizard Institute, Queen Mary University of London, London, UK.
■ 应用实例 6
K562 细胞分别使用Thapsigargin (Tg, 0.1 µM)、25、50 和 75 µM 氯喹 (CQ) 用试剂处理以诱导内质网应激和不完全自噬 24 h。使用蛋白酶体抑制剂 MG-132 (5 µM) 作为阳性对照处理24 h。将沉淀的细胞固定并透化。然后,根据制造商的说明,使用 300 µL PROTEOSTAT® 和 1 µg/mL DAPI(用于细胞周期测定)在室温下标记细胞30min。确定每个处理的S期的 Aggresome 倾向因子 (APF) 高于G1和高于S期的G2m的相对增加,并与对照值进行比较。与对照组相比,ER 应激诱导剂、Tg 和 50 µM CQ在S期比G1更能引起蛋白聚集体上调,但蛋白酶体抑制剂 MG-132 和 50 µM CQ 在 G2m 期比S期更显著地下调聚集体。
图片来源:Courtesy of the Flow Cytometry Core Facility, Blizard Institute, Queen Mary University of London, London, UK.
PROTEOSTAT® 蛋白聚集检测试剂盒 Q&A
1.Q: PROTEOSTAT® 热稳定检测试剂盒(ENZ-51027),蛋白聚集检测试剂盒(ENZ-51023)
1.Q: 和PROTEOSTAT® 蛋白聚集检测试剂盒(ENZ-51035)的区别?
1.A: 1)PROTEOSTAT®染料属于分子轮子染料(molecular rotor dye)。在溶液状态不发荧光(由于在中心的碳-碳单键周围的自由转动,
分离了探针的不同芳香部分)。由于分子轮子染料接触到蛋白聚集体后,会封闭进入原纤维,形成β折叠,具有高强度荧光。类似于
染核酸碱基的EB 一样。
1.A: 2)PROTEOSTAT® 热稳定检测试剂盒(ENZ-51027)用于直接监测热诱导蛋白变性引起的蛋白聚集,不检测蛋白非折叠而暴露的疏
水部分。该试剂盒用于检测蛋白缓冲液,其他添加成分对蛋白稳定性的影响,在特定条件下多少温度时蛋白会聚集。
1. A 3)蛋白聚集检测试剂盒(ENZ-51023)用于检测液体状蛋白或者多肽形成聚集的情况。可用于确认蛋白保存的最优形态,筛选促进或
者抑制蛋白聚集的试剂,检测分子伴侣的活性。与标准品或者已知浓度样品一起使用,可定量检测蛋白聚集。
1. A 4)PROTEOSTAT® 蛋白聚集检测试剂盒(ENZ-51035)检测变性蛋白,包括活细胞内聚集体或者聚集体样包涵体。PROTEOSTAT®
蛋白聚集检测染料在聚集小体形成时,接触到聚集蛋白时会变的更明亮,可用流式或者荧光显微镜检测。
2.Q: 使用ENZ-51035 时,是否可以终止并在在40℃过夜保存,第二天继续实验?
A: 建议可以在加染料前终止。荧光强度在液体中会成倍降低。而且染料与蛋白长时间孵育后,会影响蛋白聚集。
3.Q: 阳性对照染色不好。
A: 染料没有避光保存。染色时候没有避光,需要染色后立即检测。聚集蛋白不是液体。延长离心会使聚集蛋白沉淀。不要离心聚集蛋
白(样品或者对照)。
4.Q: 蛋白信号饱和。
A: 蛋白样品的浓度很高。用1×Assay Buffer 稀释样品。
5.Q: 阴性对照观察到高荧光强度。
A: 样品含有干扰物质。该试剂可以与常规使用的缓冲液(PBS,Tris,HEPES)和赋形剂(海藻糖和蔗糖)使用,不过不要使用高浓度的吐温
20(比如:0.2%)
6.Q: 蛋白与PROTEOSTAT® 检测试剂结合是否是可逆的?
A: PROTEOSTAT® 检测试剂与聚集蛋白的相互作用是非供价结合。所以,理论上是可逆的。但是我们没有尝试将染料从样品中去除。
7.Q: 在药物应激检测中,细胞是否可以经胰酶消化后去检测细胞中的蛋白聚集?
A: 胰酶可以与PROTEOSTAT® 聚集检测试剂盒配套使用。细胞消化后,表面活性剂加入给细胞打孔。更大的聚集体仍然是不溶的,可
以通过离心沉淀。小的聚集体通过超滤分离。表面活性剂,膜和可溶蛋白可洗掉,PROTEOSTAT® 检测试剂可用于残留蛋白。
8.Q: 在研究细胞蛋白聚集时,如何设置阳性对照?
A: MG 132 处理的细胞可作为阳性对照。
9.Q: 细胞裂解液是否可用PROTEOSTAT® 蛋白聚集检测试剂检测?
A: 检测细胞裂解液是有挑战的,表面活性剂会引起高背景。可以过滤去除表面活性剂。更大的聚集体仍然是不可溶的,可以通过
离心沉淀。小的聚集体通过超滤分离。表面活性剂,膜和可溶蛋白可洗掉,PROTEOSTAT® 检测试剂可用于残留蛋白。
10.Q: PROTEOSTAT® 染料是否可以检测~300kDa 的蛋白二聚体?
A: PROTEOSTAT® 可以检测从单体到二聚体转变的蛋白,结合分子筛层析法。但是信号会变的更强烈,因为聚集体更大。
11.Q: 如果样品稀释到低浓度(比如0.5mg/mL)是否会改变聚集蛋白的百分比含量?
A: 聚集蛋白的百分比(聚集蛋白占总蛋白的比例)将保持不变。聚集蛋白的浓度会降低,信号也会减弱。
A: 如果用未聚集蛋白稀释样品,聚体蛋白的百分比会变化。
12.Q: PROTEOSTAT® 试剂盒是否可用于研究原核细胞样品的蛋白聚集?
A: 如果膜部分去除的话,是可以检测原核细胞的。如果膜没有分离,染料会聚集在膜上,引起高背景值。
13.Q: PROTEOSTAT® 是否可检测革兰氏阴性菌的蛋白聚集?
A: 革兰氏阴性菌外层膜的脂多糖会影响。操作手册中提到的打孔缓冲液将移除大多数细菌的内层膜,破坏革兰氏阴性菌的外层膜。所以
可以观察革兰氏阴性菌的聚集和包涵体。
14.Q: 当其他蛋白共染时,如何优化减少FITC 发射过滤装置的信号?
A: 染料的激发和发射光谱见操作手册P8。光谱显示会与FITC 有些重叠。FITC 可以与该染料一起使用,用488nm激发波长和515nm 发
射波长。如果FITC 有荧光的话就会起作用。否则,PROTEOSTAT® 染料会有溢出。建立设立一个不带有FITC 标记的抗体作为对照。
另外,可用Cy5 或者Coumarin 标记的抗体解决这个问题。
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| 产品编号 | 产品名称 | 产品规格 | 产品等级 | 备注 |
| ENZ-51035-K100 | PROTEOSTAT® Aggresome detection kit PROTEOSTAT®蛋白聚集小体检测试剂盒 |
100 tests | - | - |
| ENZ-51035-0025 | PROTEOSTAT® Aggresome detection kit PROTEOSTAT® 蛋白聚集小体检测试剂盒 |
25 tests | - | - |
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